Evaluation of data compression techniques for the inference of stellar atmospheric parameters from high-resolution spectra

  1. González-Marcos, A. 1
  2. Sarro, L.M. 2
  3. Ordieres-Meré, J. 3
  4. Bello-García, A. 4
  1. 1 Universidad de La Rioja
    info

    Universidad de La Rioja

    Logroño, España

    ROR https://ror.org/0553yr311

  2. 2 Universidad Nacional de Educación a Distancia
    info

    Universidad Nacional de Educación a Distancia

    Madrid, España

    ROR https://ror.org/02msb5n36

  3. 3 Universidad Politécnica de Madrid
    info

    Universidad Politécnica de Madrid

    Madrid, España

    ROR https://ror.org/03n6nwv02

  4. 4 Universidad de Oviedo
    info

    Universidad de Oviedo

    Oviedo, España

    ROR https://ror.org/006gksa02

Revista:
Monthly Notices of the Royal Astronomical Society

ISSN: 0035-8711

Ano de publicación: 2017

Volume: 465

Número: 4

Páxinas: 4556-4571

Tipo: Artigo

DOI: 10.1093/MNRAS/STW3031 SCOPUS: 2-s2.0-85014874833 WoS: WOS:000395170200058 GOOGLE SCHOLAR

Outras publicacións en: Monthly Notices of the Royal Astronomical Society

Obxectivos de Desenvolvemento Sustentable

Resumo

The determination of stellar atmospheric parameters from spectra suffers the so-called curseof- dimensionality problem, which is related to the higher number of input variables (flux values) compared to the number of spectra available to fit a regression model (this collection of examples is known as the training set). This work evaluates the utility of several techniques for alleviating this problem in regression tasks where the objective is to estimate the effective temperature (Teff), the surface gravity (log g), the metallicity ([M/H]) and/or the alpha-to-iron ratio ([α/Fe]). The goal of the techniques analysed here is to achieve data compression by representing the spectra with a number of variables much lower than the initially available set of fluxes. The experiments were performed with high-resolution spectra of stars in the 4000-8000 K range for different signal-to-noise ratio (SNR) regimes. We conclude that independent component analysis (ICA) performs better than the rest of techniques evaluated for all SNR regimes. We also assess the necessity to adapt the SNR of the spectra used to fit a regression model (training set) to the SNR of the spectra for which the atmospheric parameters are needed (evaluation set). Within the conditions of our experiments, we conclude that at most only two such regression models are needed (in the case of regression models for effective temperatures, those corresponding to SNR = 50 and 10) to cover the entire SNR range. Finally, we also compare the prediction accuracy of effective temperature regression models for increasing values of the training grid density and the same compression techniques. © 2016 The Authors.